TY - JOUR
T1 - An MD simulation of interactions between self-interstitial atoms and edge dislocation in bcc transition metals
AU - Kamiyama, H.
AU - Rafii-Tabar, H.
AU - Kawazoe, Y.
AU - Matsui, H.
N1 - Funding Information:
The large-scalec alculationw as conductedu sing the Super Computer Center of National Institute for Fusion Science.T he authors are grateful to Prof. Moto-jima and Prof. Sato whkoi ndly enabled us to use the facility. They are indebted to the fruitful discussions with ProfessorK uramoto at RIAM, Kyushu University. The authors also thank Kubota Computer Inc. for providing the computingf acilities, and to the members of the Computer Science Group at the Institute for Materials Researchf or maintainingt he computere nvi-ronment. This work has been partially supported by the Grant-in-Aid of Ministry of Education, Science and Culture of Japan.
PY - 1994/9
Y1 - 1994/9
N2 - According to our model on the mechanism of dislocation bias reduction based on the interaction of dumbbell self-interstitial atoms (SIAs) with dislocation, the bias is significantly different depending on the dumbbell configuration in the dislocation strain field. A large-scale molecular dynamics (MD) simulation is performed to reveal the stability and the mechanism of diffusion of dumbbell SIAs near the edge dislocation core in bcc iron. Most SIAs take the crowdion configuration parallel to the Burgers vector in the expansion side of the dislocation. Such crowdions are stable in the temperature range of this simulation, i.e. between 373 and 473 K, making one-dimensional random to-and-fro motion parallel to the dislocation Burgers vector staying at several atomic layers "below" the dislocation core. This means that the SIA does not approach the dislocation core. These results suggest that the stable configuration of SIAs is seriously affected by the dislocation resulting in a reduction of bias factor.
AB - According to our model on the mechanism of dislocation bias reduction based on the interaction of dumbbell self-interstitial atoms (SIAs) with dislocation, the bias is significantly different depending on the dumbbell configuration in the dislocation strain field. A large-scale molecular dynamics (MD) simulation is performed to reveal the stability and the mechanism of diffusion of dumbbell SIAs near the edge dislocation core in bcc iron. Most SIAs take the crowdion configuration parallel to the Burgers vector in the expansion side of the dislocation. Such crowdions are stable in the temperature range of this simulation, i.e. between 373 and 473 K, making one-dimensional random to-and-fro motion parallel to the dislocation Burgers vector staying at several atomic layers "below" the dislocation core. This means that the SIA does not approach the dislocation core. These results suggest that the stable configuration of SIAs is seriously affected by the dislocation resulting in a reduction of bias factor.
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U2 - 10.1016/0022-3115(94)90062-0
DO - 10.1016/0022-3115(94)90062-0
M3 - Article
AN - SCOPUS:0028494595
SN - 0022-3115
VL - 212-215
SP - 231
EP - 235
JO - Journal of Nuclear Materials
JF - Journal of Nuclear Materials
IS - PART 1
ER -